The Number of G Residues in the Bacillus subtilis pyrG Initially Transcribed Region Governs Reiterative Transcription-Mediated Regulation

doi:10.1128/JB.01611-06

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Journal of Bacteriology, March 2007, p. 2176-2180, Vol. 189, No. 5
0021-9193/07/$08.00+0 doi:10.1128/JB.01611-06
Copyright © 2007, American Society for Microbiology. All Rights Reserved.

The Number of G Residues in the Bacillus subtilis pyrG Initially Transcribed Region Governs Reiterative Transcription-Mediated Regulation

Alexander K. W. Elsholz, Casper Møller Jørgensen, and Robert L. Switzer^*

Department of Biochemistry, University of Illinois, Urbana, Illinois 61801

Received 16 October 2006/ Accepted 1 December 2006

ABSTRACT

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Derepression of pyrG expression in Bacillus subtilis involvesCTP-sensitive reiterative transcription, which introduces upto 11 extra G residues at the 5' ends of pyrG transcripts. Insertionof three or more additional Gs at the 5' end of the pyrG initiallytranscribed region abolished reiterative transcription and causedconstitutive expression.

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Expression of the pyrG operon, which encodes CTP synthetase,is regulated in Bacillus subtilis and several other low-GC gram-positivebacteria by the intracellular CTP level (5, 8). CTP exerts itsrepressive effect by a novel mechanism that involves transcriptionattenuation at an intrinsic terminator located within an untranslatedleader region. Two short segments of conserved nucleotide sequenceare required for regulation, namely, a pyrG initially transcribedregion (ITR) with the sequence 5'-GGGC (nontranscribed strand)and a C-plus-U-rich sequence (GCUCCCUUUC in B. subtilis) locatedin the 5' strand of the attenuator-specified terminator hairpin(Fig. 1A). Evidence that supports the mechanism for pyrG regulationillustrated in Fig. 1A has been presented (8-10). Low intracellularCTP concentrations cause transcription pausing at position +4(normally a C) of the nascent pyrG transcript, which allowsreiterative transcription (also called transcriptional slippage)to occur and introduce from 1 to 11 extra G residues beforenormal elongation resumes. When the intracellular CTP levelis high, insertion of a C residue at position +4 proceeds readilywithout pausing, which precludes reiterative transcription.The extra G residues added to the 5' ends of pyrG transcriptsunder CTP limitation are proposed to act as antiterminator sequences;when present, they base pair with the C-plus-U-rich 5' strandof the terminator hairpin and preclude terminator formation(Fig. 1A). Thus, conditional reiterative transcription and theinsertion of extra G residues result in CTP-sensitive antiterminationand CTP-regulated transcription of the downstream pyrG gene.It is likely that this mechanism serves to regulate pyrG expressionin several genera of low-GC gram-positive bacteria (10).

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FIG. 1. (A) Proposed mechanism for the regulation of B. subtilis pyrG expression by CTP-sensitive reiterative transcription and antitermination (from reference 10). The 5' sequence of transcripts specified by the pyrG ITR depends on the intracellular CTP concentration. If the CTP level is high (left), a C residue is rapidly inserted at position +4 and the transcript encoded by the DNA is synthesized. This sequence permits formation of the leader terminator and reduced pyrG expression. If the CTP level is low (right), transcription pauses at +4, leading to reiterative transcription of a variable number of G residues. Transcripts bearing extra G residues are able to fold into an antiterminator hairpin, which suppresses termination and results in increased transcription of the downstream pyrG coding region. The nucleotides denoted by (N)₃₂ apparently play no role in regulation, because pyrG'-lacZ fusions from which they were deleted retained normal regulation (9). (B) Rationale for experiments reported in this work. Mutational insertion of 1 to 10 additional G residues at +1 in the pyrG ITR leads to formation of transcripts with a known number of extra 5' G residues. The effects of such mutations on reiterative transcription were determined by primer extension mapping (left). The effects of such mutations on pyrG expression were assessed with pyrG'-lacZ fusions grown under repressing and derepressing conditions (right). Note that numerous antiterminator structures can form, depending on the number of G residues inserted and the exact base pairing.

A series of pyrG transcripts with from 1 to 11 extra G residuesis formed by reiterative transcription at the wild-type pyrGITR in pyrimidine-starved cells (10). However, mutational insertionof four extra G residues at the start of the pyrG ITR (specifyingthe transcript sequence 5'-GGGGGGGC) was sufficient to causeconstitutive pyrG expression (10). In this study we sought toanswer two related questions concerning the function of theextra 5' G residues. First, given that the addition of extraG residues permits formation of a progressively more stableantiterminator structure as more Gs are added, what number ofG residues at the 5' end of pyrG transcripts is sufficient tocause fully constitutive expression? Second, what number ofG residues in the pyrG ITR is optimal for reiterative transcriptionin pyrimidine-starved cells? In other cases where reiterativetranscription has been studied, a homopolymeric run of at leastthree template residues is required for transcriptional slippage(1, 3, 4, 11). Our previous studies (10) confirmed that at leastthree G residues in the template pyrG ITR were required forreiterative transcription. However, reiterative transcriptionrequires melting of the DNA template and nascent transcriptwithin the initiation complex, so it would be expected thatthe greater stability of longer (rG)_n·(dC)_n duplexeswould suppress melting and reduce reiterative transcription.

Both of these questions were addressed by construction of mutantpyrG promoter regions in which the number of G residues in theITR was systematically increased from 3 (wild type) to 13 (Fig.1B). Reiterative transcription in vivo with templates bearingseveral of the G_n insertions was characterized by primer extensionmapping of the 5' ends of pyrG transcripts to determine theirlengths and relative amounts, as previously described by Menget al. (10) (Fig. 2). Derivatives of the high-copy plasmid pEB112(6) containing the wild-type pyrG promoter-leader region (nucleotides–49 to +81) and mutants of this region in which one, two,three, and eight G residues were inserted into the ITR wereconstructed as described by Meng et al. (10) and used to transformB. subtilis HC-11 (pyrB::Spc^r). The pyrimidine auxotrophic pyrBhost was used so that the cells could be starved for pyrimidinesby growth on orotate, which is a poor pyrimidine source forB. subtilis (8, 9). Growth of the strain with cytidine, on theother hand, represses pyrG expression. High-copy plasmids containingthe pyrG regions were used to produce transcripts at levelsmuch higher than the background levels of transcripts producedfrom the wild-type chromosomal pyrG operon also present in strainHC-11 (which were barely detectable under the conditions used).The transformed cells were grown in minimal medium containingcytidine or orotate, i.e., repressing and derepressing conditions,respectively, and RNA was harvested from the cells as previouslydescribed (10). A single-stranded DNA (primer C) complementaryto nucleotides +15 to +34 of the pyrG transcript was chemicallysynthesized and 5' end labeled with [ ${gamma}$ -³³P]ATP and T4 polynucleotidekinase. The labeled DNA was used as the primer for avian myeloblastosisvirus reverse transcriptase, and the primer-extended productswere analyzed by electrophoresis as described previously (10).Transcripts specified by the wild-type pyrG plasmid and harvestedfrom cells grown with excess cytidine mapped to the +1 positionof the ITR, as previously reported (8, 10). In this assay transcriptsthat were one to four nucleotides longer were also detectedin cells grown with excess cytidine (Fig. 2, WT +C). These longertranscripts may indicate that limited reiterative transcriptionoccurred even under repressing conditions, but we believe thatthey are largely an artifact of using templates borne on multicopyplasmids, because they were much less prominent when transcriptsfrom the chromosomal pyrG operon were analyzed (8, 10). Extensivereiterative transcription occurred in pyrimidine-starved cellswith the wild-type template, as shown by the formation of aladder of primer-extended products, corresponding to transcriptswith extensions up to 11 nucleotides long. We have previouslydemonstrated that these extensions are formed by the additionof extra 5' G residues (10). The most abundant poly(G) extensionsranged from 4 to 10 nucleotides long (Fig. 2, WT +Oro).

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FIG. 2. Primer extension mapping of pyrG transcripts extracted from the pyrimidine-requiring B. subtilis strain HC-11 bearing pEB112-derived plasmids that contained the promoter-leader region of wild-type pyrG (WT) or the corresponding region with (G)_n insertion mutations (+1G, +2G, +3G, and +8G). Cells were grown on minimal medium (8) at 37°C with excess cytidine (+C) or orotate (+Oro), a poor pyrimidine source, and were harvested in mid-exponential phase as previously described (8). The sequencing ladder is labeled to correspond to the sequence of the nontranscribed strand. The arrow denotes G +1, the previously identified (10) transcription initiation site encoded by the pyrG gene. The position of 5'-end-labeled primer C (10), used both for sequencing and primer extension, is also shown.

When the transcripts specified by plasmids carrying pyrG ITRscontaining one, two, three, or eight G insertions were mapped,the shortest transcripts from cells grown under repressing conditionswere longer than the wild-type transcripts by one, two, three,and eight nucleotides, respectively, as expected. As with thewild-type template, some marginally extended transcripts wereformed in repressed cells when the template contained insertionsof one or two G residues, but these transcripts were much lessabundant with the templates containing three and eight G insertions.This observation indicates that an ITR sequence of longer thanfive G residues suppresses reiterative transcription. This conclusionis reinforced by the mapping of transcripts from the same strainsgrown under derepressing conditions. A ladder of longer transcriptssimilar to that seen with the wild-type template was formedin starved cells containing the pyrG template with a singleG insertion. When the template contained two inserted G residues,the ladder of transcripts also indicated the occurrence of reiterativetranscription in pyrimidine-starved cells, but the ladder wassomewhat shorter than that found with the wild-type template,and only a few of the transcripts were longer than those observedwith repressed cells. When the pyrG template contained threeor eight inserted G residues, little reiterative transcriptionoccurred under any condition.

It was demonstrated previously that reiterative transcriptionat the pyrG ITR requires a run of three G residues at the siteof transcription initiation, followed by a C or T residue (10).Here we have demonstrated that a run of four or five G residuesalso permits reiterative transcription, but a run of six ormore G residues suppresses it. As noted above, reiterative transcriptionrequires melting of the hybrid formed by the DNA template andthe nascent transcript, so the greater stability of the (rG)_n·(dC)_nduplex when n is greater than 5 may preclude reiterative transcriptionby suppressing melting.

The effect of various G insertions on expression of correspondingpyrG'-lacZ fusions integrated into the B. subtilis chromosomewas also determined. Derivatives of the pDH32 integration plasmid(2) that contained pyrG'-lacZ fusions bearing either the wild-typepyrG promoter-leader region (nucleotides –49 to +81),which specifies transcripts initiating with 5'-GGGCUC, or mutatedpyrG promoter-leader regions that specified transcripts initiatingwith 5'-GGG(G)_nCUC (where n equals 1, 2, 3, 4, 6, 8, and 10)were constructed using previously published procedures (8, 9).DNA sequencing confirmed the identities of the pyrG' regionsof the plasmids. The plasmids were integrated into the amyElocus of the chromosome of B. subtilis strain HC-11 (pyrB::Spc^r)as described previously (8). (Note that two of these stains,QM401 and QM425, were prepared previously [8, 10].) The integrantstrains were grown on minimal medium containing 200 µgof cytidine per ml (repressing conditions) and on the same mediumcontaining 100 µg of orotate per ml (derepressing conditions),and ß-galactosidase assays were used to assess pyrGexpression under both conditions using published methods (8).As seen in previous studies (8, 9), expression of the wild-typepyrG'-lacZ fusion was derepressed 14-fold by growth under pyrimidine-limitingconditions, relative to growth on excess cytidine (Table 1).Insertion of even a single G residue in the pyrG ITR led tosubstantial derepression of expression. Insertion of two ormore G residues resulted in essentially constitutive pyrG expression(Table 1). (The residual 1.8- to 2.5-fold-higher level of expressionin pyrimidine-starved cells containing three or more insertedG residues was previously observed in a pyrG'-lacZ fusion inwhich the attenuator terminator was deleted [8] and resultsfrom a phenomenon unrelated to transcription attenuation.) Thehighest level of pyrG expression under both repressing and derepressingconditions was observed with the pyrG'-lacZ fusion containingfour inserted G residues.

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TABLE 1. Effects of G insertion mutations on expression of pyrG-lacZ fusions in repressed and pyrimidine-starved B. subtilis HC-11 cells

Interpretation of the effects of the G insertions on pyrG'-lacZexpression is complex, because the insertions have two consequencesthat are expected to have opposite effects on pyrG expression.Reiterative transcription is necessary to generate the 5' poly(G)tails on pyrG transcripts that act as the antiterminator andsuppress the downstream attenuator. From this considerationalone, one would predict that the fusions in which reiterativetranscription occurred, i.e., those with one and two G insertions(Fig. 2, +1G and +2G), would behave more or less like the wildtype and that those containing three or more G insertions, inwhich reiterative transcription was suppressed (Fig. 2, +3Gand +8G), would fail to antiterminate and would be repressedunder all growth conditions. In fact, all of the G insertionmutants were expressed at elevated levels; that is, they failedto terminate normally under repressing conditions. The pyrG'-lacZfusion containing a single G insertion showed some residualregulation, which presumably resulted from its ability to carryout reiterative transcription, but was expressed at an elevatedlevel under repressing conditions, compared to the wild-typefusion. Insertions of two or more G residues led to constitutiveexpression, whether reiterative transcription occurred or not.Examination of the patterns of transcript formation in theseinsertion strains (Fig. 2) leads us to suggest that derepressionresults from formation of pyrG transcripts containing six ormore G residues at their 5' ends, whether these result fromreiterative transcription (wild type and one and two G insertions)or are encoded in the pyrG template (three or more G insertions).While a 5'-GGGGGG segment of the transcript is apparently sufficientto serve as an antiterminator by base pairing with the downstreamGCUCCCUUUC segment of the attenuator hairpin, the highest levelof expression was obtained with the four-G insertion mutant(Table 1), corresponding to a 5' poly(G) tract of seven residues.The most abundant poly(G) tracts formed by reiterative transcriptionin pyrimidine-starved cells with the wild-type pyrG templatecontained 7 to 13 G residues (Fig. 2, WT +Oro), which are clearlysufficient for optimal antitermination.

It is evident that the pyrG DNA has been selected to containthe optimal number of rG-dC base pairs specifying the 5' terminusof its transcripts; that number is three. A pyrG template specifyingtwo G residues in the transcript, i.e., one in which one ofthe three wild-type G residues is mutated to A, fails to carryout significant reiterative transcription (10), cannot antiterminate,and is expressed at very low levels (9). A pyrG template specifyingfour G residues is capable of reiterative transcription butantiterminates to a significant degree even under repressingconditions, leading to suboptimal regulation. Templates specifyingfive or more G residues are progressively more defective inreiterative transcription and antiterminate under all conditions.

Our studies identified that a 5' poly(G) sequence containingsix G residues is highly effective in antitermination of pyrGexpression, and a 5' poly(G) sequence of seven to nine G residuesis optimal for antitermination. However, the stability of theputatively optimal antiterminator stem-loop structure with (G)₉Cbase paired to the terminator sequence GCUCCCUUUC, as calculatedusing Mfold (12), is approximately equal to the calculated stabilityof the B. subtilis pyrG leader terminator (attenuator) stem-loop,whereas antiterminator structures with fewer G residues areprogressively weaker by about 0.5 kcal/mol per G residue. (Numerouspossible structures are predicted by Mfold, depending on theexact sequences folded and constraints used, so such computationsshould be interpreted cautiously.) We suggest that the competitionin vivo between antiterminator and terminator conformationsof pyrG leader RNA does not occur as a simple thermodynamicequilibrium between the two folded forms. If it did, terminationwould be expected to equal or exceed antitermination even underderepressing conditions. Rather, we predict that the systemis kinetically controlled. We propose that during pyrimidinestarvation reiterative transcription leads to formation of 5'poly(G) tracts on the transcripts that are able to form theantiterminator structure before the terminator is fully transcribedand emergent from RNA polymerase. By the time the terminatoris able to form and compete with the antiterminator structure,transcription has proceeded through the terminator sequence,and RNA polymerase is committed to transcription of the entiredownstream pyrG coding region. Only in the absence of the upstream5' poly(G) tracts and the consequent absence of interfering(albeit transient) antiterminator formation is the pyrG leaderterminator able to form quickly enough to terminate within theleader region.

Reiterative transcription occurs when nucleotides are addedrepetitively to the 3' end of a nascent transcript after thattranscript slips toward the 5' end relative to the DNA templatestrand. Slippage of the transcript generally occurs when RNApolymerase pauses because it is unable to add the next encodednucleotide. The slippage site is a homopolymeric sequence, atleast three nucleotides in length, on the template that specifiesa complementary sequence in the transcript (GGG in pyrG), whichundergoes elongation to longer homopolymeric segments (4). Veryfew systematic studies of the dependence of reiterative transcriptionon the length of the homopolymeric slippage site in the templateare available, and most have studied reiterative transcriptionin vitro, not in vivo, as in this work. We have identified onlyone other example of reiterative transcription yielding poly(G)addition at the 5' end of transcripts, namely, that catalyzedby T7 RNA polymerase with GTP only and a template specifying5'-GGGN transcripts (7). In this case a template specifyingtwo Gs or one G sharply reduced or abolished reiterative transcription,respectively. Templates specifying a sequence of four or moreGs were not studied. Reiterative transcription has been observedmore frequently when the template specifies a tract of U orA residues at the 5' end of the transcript (4). In several suchcases the effects of substitution mutations in the homopolymericsegments of the template documented that a run of at least threeT or A residues was required (1, 3, 11). However, only in thestudies by Cheng et al. (1) of reiterative transcription andregulation of the Escherichia coli upp promoter was the effectof length of the homopolymeric segment of T residues in thetemplate systematically examined. These workers found that aminimum of three T residues in the template was required forreiterative transcription of U residues in the upp transcript.Stepwise variation in the number of template Ts from three toeight did not alter reiterative transcription significantlyin vitro but appeared to increase it in vivo, as judged fromthe regulation of corresponding upp-lacZ fusions. This lengthdependency is quite different from that observed in our studieswith reiterative transcription of G residues with the pyrG template.From these differences it seems likely that the detailed dependenceof reiterative transcription on template sequence will differfrom system to system. It should be noted, however, that themechanism of regulation of upp expression by reiterative transcriptiondiffers markedly from the mechanism of pyrG regulation. In theupp system reiterative transcription of U residues at high UTPlevels leads to abortive initiation and reduced expression,whereas reiterative transcription at the pyrG ITR occurs atlow CTP levels and leads to antitermination and elevated expression.

ACKNOWLEDGMENTS

We gratefully acknowledge Qi Meng for providing B. subtilisstrains QM401 and QM425 and developing the methods used in thiswork and Charles L. Turnbough, Jr., for valuable comments onthe manuscript.

This research was supported by Public Health Service grant GM47112from the National Institute of General Medical Studies.

FOOTNOTES

* Corresponding author. Mailing address: Department of Biochemistry, University of Illinois, 600 South Mathews, Urbana, IL 61801. Phone: (217) 333-3940. Fax: (217) 244-5858. E-mail: rswitzer{at}uiuc.edu.

Published ahead of print on 8 December 2006.

Present address: Institute for Microbiology, Ernst-Moritz-Arndt-University,Friedrich-Ludwig-Jahn-Strasse 15, D-17487 Greifswald, Germany.

REFERENCES

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Cheng, Y., S. M. Dylla, and C. L. Turnbough, Jr. 2001. A long T-A tract in the upp initially transcribed region is required for regulation of upp expression by UTP-dependent reiterative transcription in Escherichia coli. J. Bacteriol. 183:221-228.[Abstract/Free Full Text]

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Turnbough, C. L. Jr., Switzer, R. L. (2008). Regulation of Pyrimidine Biosynthetic Gene Expression in Bacteria: Repression without Repressors. Microbiol. Mol. Biol. Rev. 72: 266-300 [Abstract] [Full Text]

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